CN217274454U - Distributed ecological heat supply haze removal energy station - Google Patents

Abstract

The embodiment of the application relates to a haze energy station is removed in distributed ecological heat supply, comprising a tower body, establish the aeration tank in the tower body bottom, establish in the aeration tank and the aeration nest of tubes's input stretches out from the tower body aeration nest of tubes, establish in the tower body and be located the condenser of aeration tank top, establish in the tower body and be located the heat transfer nest of tubes top, establish outside the tower body and with the heat transfer nest of tubes be connected the unit and establish the gas input on the tower body, gas input is used for to the input gas between condenser and the heat transfer nest of tubes. The distributed ecological heat supply haze removal energy station disclosed by the embodiment of the application improves the quality of nearby air through adsorption treatment on the sucked air.

Description

Distributed ecological heat supply haze removal energy station

Technical Field

The application relates to the technical field of environment and energy, in particular to a distributed ecological heat supply haze removal energy station.

Background

Distributed ecological heat supply has acquired more market demands due to factors such as small volume, convenient deployment and the like, and the combination of heat supply and air pollution control can meet more market demands in consideration of the use scene and the improvement of the current air quality requirement.

Disclosure of Invention

The embodiment of the application provides a haze energy station is removed in distributed ecological heat supply, improves the quality of near air through the absorption treatment to the inhaled air.

The above object of the embodiments of the present application is achieved by the following technical solutions:

the embodiment of the application provides a haze energy station is removed in distributed ecological heat supply, include:

a tower body;

the aeration tank is arranged at the bottom of the tower body;

the aeration pipe group is arranged in the aeration tank, and the input end of the aeration pipe group extends out of the tower body;

the condenser is arranged in the tower body and is positioned above the aeration tank;

the heat exchange tube set is arranged in the tower body and is positioned above the condenser;

the unit is arranged outside the tower body and connected with the heat exchange tube group; and

and the gas input end is arranged on the tower body and used for inputting gas between the condenser and the heat exchange tube group.

In a possible implementation manner of the embodiment of the application, the heat exchange tube group includes a plurality of heat exchange tubes, and the heat exchange tubes are arranged in an MxN matrix;

the input end of the heat exchange pipeline is higher or lower than the output end.

In a possible implementation manner of the embodiment of the application, a plurality of fins are arranged on the heat exchange pipeline at intervals;

one end of the fin close to the aeration tank inclines towards the lower end of the heat exchange pipeline.

In a possible implementation manner of the embodiment of the application, a water level sensor is arranged in the aeration tank;

the device also comprises a water supply module connected with the aeration tank;

the water level sensor is used for monitoring the lowest water level in the aeration tank and feeding back a water supplementing signal to the water supply module.

In one possible implementation manner of the embodiment of the application, the number of the aeration pipe groups is multiple, and the starting number of the aeration pipe groups is determined according to the input air volume.

In one possible implementation manner of the embodiment of the application, the aeration tube groups are divided into two groups, and the number of the aeration tube groups in each group is multiple;

the first group of aeration pipe groups are positioned above the second group of aeration pipe groups;

the first group of aeration pipe groups and the second group of aeration pipe groups are both positioned below the water level sensor.

Drawings

Fig. 1 is a schematic structural diagram of a distributed ecological heat supply haze removal energy station provided by an embodiment of the application, and arrows in the diagram show a flow direction.

Fig. 2 is another operation diagram based on fig. 1.

In the figure, 11, a tower body, 12, an aeration tank, 13, an aeration pipe group, 14, a condenser, 15, a heat exchange pipe group, 16, a machine set, 17, a gas input end, 151, a heat exchange pipeline, 152, a fin, 2, a water level sensor, 3 and a water supply module are shown.

Detailed Description

The technical solution of the present application will be described in further detail below with reference to the accompanying drawings.

Referring to fig. 1 and 2, for a distributed ecological heat supply haze removal energy station disclosed in the embodiment of the present application, the energy station is composed of a tower body 11, an aeration tank 12, an aeration pipe set 13, a condenser 14, a heat exchange pipe set 15, a unit 16, a gas input end 17, and the like, specifically, the aeration tank 12 is located at the bottom of the tower body 11, the aeration pipe set 13 is disposed in the aeration tank 12, and the input end of the aeration pipe set 13 extends out of the tower body 11, and is used for aerating air flowing into the tower body 11.

A condenser 14 is fixedly installed in the tower body 11 above the aeration tank 12 and serves to remove most of the water from the aerated gas. The heat exchange tube set 15 is disposed in the tower body 11 above the condenser 14, and functions to exchange heat with air flowing into the tower body 11.

The unit 16 is disposed outside the tower body 11, connected with the heat exchange tube set 15, and composed of a condenser evaporator, a tube set, a fan, a driving device and the like, and is used for driving a heat exchange medium to flow so as to complete conversion from a low-quality heat source to a high-quality heat source.

Gas input 17 sets up on tower body 11 for to input gas between condenser 14 and the heat exchange tube group 15, like this, outside air is flowed in by gas input 17 when not needing to remove the haze, and outside air is flowed in by aeration nest of tubes 13 when needing to remove the haze.

On the whole, the ecological heat supply of distributed type that this application embodiment discloses removes haze energy station can remove the haze when needs remove the haze to the air that flows into in the tower body 11 after removing the heat exchange, then directly carries out the heat exchange to the air that flows into in the tower body 11 when not needing to remove the haze, and the using-way is more nimble.

The specific switching can be realized by a fan and two groups of pipelines with valves, the two groups of pipelines are respectively connected with the aeration pipe group 13 and the gas input end 17, and the switching of the input gas circuit is realized by changing the opening and closing of the valves.

Referring to fig. 1 and fig. 2, as an embodiment of the distributed ecological heat supply and haze removal energy station provided in the application, the heat exchange tube group 15 includes a plurality of heat exchange tubes 151, the heat exchange tubes 151 are arranged in an MxN matrix, and meanwhile, an input end of the heat exchange tube 151 is higher or lower than an output end.

On the one hand, can increase the quantity of heat transfer pipeline 151 like this, obtain higher heat transfer area, on the other hand, can make the comdenstion water that produces on the heat transfer pipeline 151 outer wall flow to low from the eminence fast, fall in the aeration tank 12 of below after gathering.

Referring to fig. 1 and fig. 2, as a specific embodiment of the distributed ecological heat supply and haze removal energy station provided by the application, a plurality of fins 152 are arranged on the heat exchange pipeline 151 at intervals, and the fins 152 also serve to increase the contact area.

Moreover, one end of the fin 152 close to the aeration tank 12 is inclined towards the lower end of the heat exchange pipe 151, so that on one hand, the contact area between the fin 152 and air can be increased, and on the other hand, after condensed water on the heat exchange pipe 151 flows to the junction of the heat exchange pipe 151 and the fin 152, the condensed water can quickly flow onto the fin 152 and fall off from the fin 152.

Referring to fig. 1 and 2, as a specific embodiment of the distributed ecological heat supply haze removal energy station provided by the application, a water level sensor 2 and a water supply module 3 are further added, the water level sensor 2 is located in the aeration tank 12 for monitoring the lowest water level in the aeration tank 12, and the water supply module 3 is connected with the aeration tank 12 and is used for supplementing water into the aeration tank 12.

After the water level sensor 2 feeds back a water supplementing signal to the water supply module 3, the water supply module 3 is started to supplement water into the aeration tank 12, and after the supplementing amount reaches the set amount, the water supply module 3 stops working. It should be understood that the water level in the aeration tank 12 is low, which affects the contact between the gas and the water, so that the minimum water level needs to be monitored by the water level sensor 2.

Referring to fig. 1 and 2, as a specific embodiment of the distributed ecological heat supply and haze removal energy station provided by the application, a plurality of aeration tube sets 13 are provided, and the number of the aeration tube sets 13 to be used is determined according to the input air volume. It will be appreciated that the input air flow is power dependent, and that the number of operations of the aeration tube bank 13 also needs to be reduced appropriately when the input power is adjusted to be low.

Further, the aeration tube groups 13 are divided into two groups, the number of the aeration tube groups 13 in each group is plural, the first group of aeration tube groups 13 is located above the second group of aeration tube groups 13, and the water level sensor 2 is placed above the first group of aeration tube groups 13 and the second group of aeration tube groups 13.

When two sets of aeration nest of tubes 13 simultaneous workings, even meet the circumstances that the surface of water descends, second group aeration nest of tubes 13 still can keep normal work, can carry out normal haze work that removes.

The embodiments of the present invention are preferred embodiments of the present application, and the scope of protection of the present application is not limited by the embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (6)

1. The utility model provides an ecological heat supply of distributing type removes haze energy station which characterized in that includes:

a tower (11);

the aeration tank (12) is arranged at the bottom of the tower body (11);

the aeration pipe group (13) is arranged in the aeration tank (12), and the input end of the aeration pipe group (13) extends out of the tower body (11);

the condenser (14) is arranged in the tower body (11) and is positioned above the aeration tank (12);

the heat exchange tube set (15) is arranged in the tower body (11) and is positioned above the condenser (14);

the unit (16) is arranged outside the tower body (11) and is connected with the heat exchange pipe set (15); and

and the gas input end (17) is arranged on the tower body (11) and is used for inputting gas between the condenser (14) and the heat exchange tube set (15).

2. The distributed ecological heat supply haze removal energy station according to claim 1, wherein the heat exchange tube set (15) comprises a plurality of heat exchange tubes (151), the heat exchange tubes (151) are arranged in a matrix of MxN;

the input end of the heat exchange pipe (151) is higher or lower than the output end.

3. The distributed ecological heat supply haze removal energy station according to claim 2, wherein a plurality of fins (152) are arranged on the heat exchange pipeline (151) at intervals;

one end of the fin (152) close to the aeration tank (12) inclines towards the lower end of the heat exchange pipeline (151).

4. A distributed ecological heat and haze energy station according to any one of claims 1 to 3, wherein a water level sensor (2) is arranged in the aeration tank (12);

the device also comprises a water supply module (3) connected with the aeration tank (12);

the water level sensor (2) is used for monitoring the lowest water level in the aeration tank (12) and feeding back a water supplementing signal to the water supply module (3).

5. A distributed ecological heat and haze energy station according to claim 4, wherein the number of the aeration pipe sets (13) is multiple, and the number of the aeration pipe sets (13) is determined according to the input air volume.

6. A distributed ecological heat and haze energy station according to claim 5, wherein the aeration tube sets (13) are divided into two groups, and the number of the aeration tube sets (13) in each group is more than one;

the first group of aeration pipe groups (13) are positioned above the second group of aeration pipe groups (13);

the first group of aeration pipe groups (13) and the second group of aeration pipe groups (13) are both positioned below the water level sensor (2).

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